KR20130134453A - Preheating device of submerged entry nozzle - Google Patents

Abstract

The present invention relates to a device for preheating immersion nozzles and, more specifically, to the device for preheating the immersion nozzles to reduce economical loss and improving production efficiency of a continuous casting process by preventing molten steels from being coagulated in the internal diameter of the immersion nozzle. Provided is the device comprising: a housing limiting the preheated immersion nozzle in the inside; a holder in which the upper part of the immersion nozzle to be preheated is held; an air and gas supply line held in the holder, opened by pressure of the immersion nozzle, and supplying air and fuel gas into the housing; an ignition member operating an igniter arranged inside the housing by sensing an opening state of the air and gas supply line. [Reference numerals] (154) Control unit

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a preheating device for a submerged nozzle,

The present invention relates to an immersion nozzle preheating apparatus, and more particularly, to an immersion nozzle preheating apparatus for reducing the phenomenon of solidification of molten steel in an inner diameter of an immersion nozzle, lowering economic loss, and increasing production efficiency of continuous casting.

In general, a continuous casting machine is a facility for producing a slab of a predetermined size by receiving molten steel produced in a steelmaking furnace and transferred to a ladle in a turndish and supplying it as a mold for a continuous casting machine.

The continuous casting machine includes: a ladle for storing molten steel; a continuous casting mold for casting a tundish and molten steel guided in the tundish to form a casting having a predetermined shape; and a casting mold connected to the casting mold, And a plurality of pinch rollers for moving the pinch rollers.

In other words, molten steel introduced from the ladle and the tundish is formed into a casting such as a slab, a bloom, or a billet having a predetermined width and thickness in the mold and is conveyed through the pinch roller.

A related prior art is Korean Patent No. 0773833 (registered on October 31, 2007, entitled "Immersion nozzle for melting mold plus").

An object of the present invention is to provide an immersion nozzle preheating device for reducing the phenomenon of solidification of molten steel in the inner diameter of the immersion nozzle, lowering the economic loss, and increasing the production efficiency of continuous casting.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above.

The immersion nozzle preheating apparatus of the present invention for achieving the above object is a housing in which the lower portion of the immersion nozzle preheated through the insertion hole of the upper surface is limited to the inside; A holder on which the upper portion of the immersion nozzle to be preheated is mounted; An air supply line and a gas supply line extending into the housing with an air supply valve and a gas supply valve opened by the pressure of the immersion nozzle mounted on the mount; And ignition means for sensing an open state of the air supply valve and the gas supply valve to ignite the ignition fluid supplied into the housing.

Specifically, the cradle includes: a cylinder vertically disposed on the upper surface of the housing so as not to interfere with the insertion hole; A rod ascending and descending along the interior of the cylinder; And a mounting ring disposed on an upper part of the rod and mounted on an upper part of the immersion nozzle inserted into the insertion hole of the housing.

On the other hand, the cylinder, the air supply valve, and the gas supply valve are connected by an opening / closing flow path, and the air supply valve and the gas supply valve are connected to each other by an opening / closing flow path in which the pressure is raised and lowered by the immersion nozzle, As shown in Fig.

And the ignition means comprises an igniter disposed within the housing adjacent to the proximal end of the air supply line and the gas supply line; And a control unit for operating the igniter by detecting an open state of the air supply valve and the gas supply valve.

It may also include an insertion hole on the upper surface of the housing and an exhaust port that is disposed unobtrusively on the mount.

INDUSTRIAL APPLICABILITY As described above, the immersion nozzle preheating apparatus according to the present invention can easily preheat the immersion nozzle, and can solve the inconvenience of the immersion nozzle preheating operation.

Further, by providing a plurality of preheating apparatuses according to the present invention, it is possible to preheat a plurality of immersion nozzles, and it is possible to prevent operating accidents due to preheating of the immersion nozzle due to lack of preheating facilities.

Fig. 1 is a view for explaining the continuous casting machine of Fig. 1 centered on the flow of molten steel,
2 is a perspective view of the immersion nozzle preheating apparatus according to the present invention, and
FIG. 3 is a state of use of the immersion nozzle preheating apparatus shown in FIG. 2. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same components are denoted by the same reference symbols whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a conceptual diagram showing a continuous casting machine according to an embodiment of the present invention mainly on the flow of molten steel.

Continuous casting is a casting process in which a molten metal is continuously cast and a steel ingot is extracted while solidifying it in a bottomless mold. Continuous casting is used to manufacture slabs, blooms and billets, which are mainly rolled materials, and long products of simple cross-section such as square, rectangle, and circle.

The shape of a continuous casting machine is classified into a vertical type and a vertical bending type. In Fig. 1, a vertical bending type is illustrated.

Referring to FIG. 1, the continuous casting machine may include a ladle 10, a tundish 20, a mold 30, secondary cooling tables 60 and 65, and a pinch roll 70.

The tundish 20 is a container that receives the molten metal from the ladle 10 and supplies the molten metal to the mold 30. In the tundish 20, the supply rate of the molten metal flowing into the mold 30 is controlled, the molten metal is distributed to each mold 30, the molten metal is stored, and the slag and the nonmetallic inclusions are separated.

The mold 30 is typically made of water-cooled copper and allows the molten steel to be primary cooled. The mold 30 has a pair of structurally opposed faces open to form a hollow portion for receiving molten steel. In the case of manufacturing the slab, the mold 30 includes a pair of barriers and a pair of end walls connecting the barriers. Here, the end wall has a smaller area than the barrier. The walls of the mold 30, mainly short walls, may be rotated away from or close to each other to have a certain level of taper. This taper is set to compensate for the shrinkage due to the solidification of the molten steel M in the mold 30. The degree of solidification of the molten steel (M) will vary depending on the carbon content, the type of powder (steel cold Vs slow cooling), casting speed and the like depending on the steel type.

The mold 30 is formed such that a solidified shell or a solidified shell 81 is formed so as to maintain the shape of the casting pluck pulled out from the mold 30 and to prevent the molten metal from being hardly outflowed from flowing out. . The water-cooling structure includes a method using a copper tube, a method of water-cooling the copper block, and a method of assembling a copper tube having a water-cooling groove.

The mold 30 is osillated by the oscillator 40 to prevent molten steel from sticking to the wall surface of the mold. Lubricant is used to reduce friction between the mold 30 and the solidification shell 81 and prevent burning during oscillation. As the lubricant, there is oil to be sprayed and powder added to the molten metal surface in the mold 30. The powder is added to the molten metal in the mold 30 to become slag so that the lubricating of the mold 30 and the solidifying shell 81 as well as the prevention and nitriding of the molten metal in the mold 30 and the warming, It also functions to absorb non-metallic inclusions. A powder feeder 50 is installed to feed the powder into the mold 30. The portion of the powder feeder 50 for discharging the powder is directed to the inlet of the mold 30.

The secondary cooling zones 60 and 65 further cool the molten steel primarily cooled in the mold 30. The primary cooled molten steel is directly cooled by the spraying means 65 for spraying water while being maintained by the support roll 60 so that the coagulation angle is not deformed. The solidification of the cast steel is mostly made by the secondary cooling.

The drawing device adopts a multidrive method using a pair of pinch rolls 70 and the like so as to pull out the cast pieces without slipping. The pinch roll 70 pulls the solidified tip of the molten steel in the casting direction, thereby allowing the molten steel passing through the mold 30 to continuously move in the casting direction.

The continuous casting machine configured as described above allows the molten steel M accommodated in the ladle 10 to flow into the tundish 20. For this flow, the ladle 10 is provided with a shroud nozzle 15 extending toward the tundish 20. The shroud nozzle 15 extends into the molten steel in the tundish 20 so that the molten steel M is not exposed to the air to be oxidized and nitrided.

The molten steel M in the tundish 20 is caused to flow into the mold 30 by the submerged entry nozzle 25 extending into the mold 30. The immersion nozzle 25 is disposed at the center of the mold 30 so that the flow of the molten steel M discharged from both the discharge ports of the immersion nozzle 25 can be made symmetrical. The start, discharge speed, and stop of the discharge of the molten steel M through the immersion nozzle 25 are determined by a stopper 21 installed in the tundish 20 corresponding to the immersion nozzle 25. Specifically, the stopper 21 may be vertically moved along the same line as the immersion nozzle 25 to open and close the inlet of the immersion nozzle 25. The control of the flow of the molten steel M through the immersion nozzle 25 may be performed by a slide gate method different from the stopper method. The slide gate controls the discharge flow rate of the molten steel (M) through the immersion nozzle (25) while the plate material slides horizontally in the tundish (20).

Molten steel (M) in the mold (30) starts to solidify from a portion in contact with the wall surface of the mold (30). This is because the periphery of the molten steel M is liable to lose heat by the water-cooled mold 30. The rear portion along the casting direction of the cast slab 80 is formed into a shape in which the non-solidified molten steel 82 is wrapped in the solidifying shell 81 by the method in which the peripheral portion first coagulates.

As the pinch roll 70 pulls the front end portion 83 of the completely cast solid cast steel 80, the unsolidified molten steel 82 moves together with the solidified shell 81 in the casting direction. The non-solidified molten steel (82) is cooled by the spraying means (65) for spraying the cooling water in the up-shifting process. This causes the thickness of the non-solidified molten steel (82) to gradually decrease in the cast steel (80). When the cast steel 80 reaches one point 85, the cast steel 80 is filled with the solidification shell 81 of the entire thickness. The solidification casting 80 having been solidified is cut to a predetermined size at the cutting point 91 and is divided into a slab P such as a slab or the like.

2 is a perspective view showing the immersion nozzle preheating apparatus according to the present invention, the immersion nozzle preheating apparatus 100 according to the present invention, the housing 110 for defining the lower part of the preheated immersion nozzle 25-1, Arranged to be elevated on the upper portion of the housing 110, by the pressure of the cradle 120, the immersion nozzle 25-1 is mounted on the cradle 120, the top of the immersion nozzle 25-1 to be preheated The igniter 140 which is opened and senses an open state of the air and gas supply lines 130 and 140 and the air and gas supply lines 130 and 140 to supply air and fuel gas into the housing 110 is disposed inside the housing 110. Ignition means 150 for operating the.

The housing 110 has a hollow shape inside. An insertion hole 114 communicating with the inside of the housing 110 is formed on the upper surface of the housing 110. In the insertion hole 114, the lower portion of the immersion nozzle 25-1 to be preheated is inserted. An exhaust port 112 is disposed on the upper surface of the housing 110 so as not to interfere with the insertion hole 114 and the cradle 120 described later. The exhaust port 112 allows the combustion gas generated in the housing 110 to be discharged when the immersion nozzle 25-1 is preheated.

Preferably, the housing 110 can be designed with a dual structure to enhance durability. More preferably, the housing 110 in FIGS. 2 and 3 is shown as a rectangular housing shape, but the housing 110 is not limited to a rectangular housing shape.

The housing 110 thus formed is provided with a cradle 120, an air supply line 130, a gas supply line 140, and an ignition means 150.

The holder 120 includes at least one cylinder 124 vertically disposed on the upper surface of the housing 110 so as not to interfere with the insertion hole 114, a rod 126 ascending and descending along the inside of the cylinder 124, And a mounting ring 122 which is disposed on the top of the rod 126 and on which the upper portion of the immersion nozzle 25-1 inserted into the insertion hole 114 of the housing 110 is mounted. The cradle 120 is connected to the air supply line 130 and the gas supply line 140. The air supply line 130 and the gas supply line 140 are connected to the housing 110 through the outside of the housing 110, And extend into the interior of the housing 110 through the lower surface.

The air supply valve 132 and the gas supply valve 142 are disposed in the cylinder 124 and the air supply line 130 and the gas supply line 140. The air supply valve 132 and the gas supply valve 142 Closing valve 128 for connecting the cylinder 124 to the air supply valve 132 and the gas supply valve 142 are connected to the control valve 128. [

That is, when the rod 126 is lowered to the lower portion of the cylinder 124 by the pressure of the immersion nozzle 25-1 mounted on the mounting ring 122, the pressure of the working fluid in the switching valve 128 rises Whereby the air supply valve 132 and the gas supply line 142 are opened to allow air and gas to be fed into the housing 110.

Conversely, when the immersion nozzle is removed and the lower portion of the cylinder rises, the pressure of the working fluid in the switching valve 128 is lowered, thereby closing the air supply valve 132 and the gas supply valve 142.

On the other hand, the ignition means 150 includes a normal igniter 152 and a control portion 154 for operating the igniter 152 by sensing the open state of the air supply valve 132 and the gas supply valve 142.

The igniter 152 is disposed adjacent to an extension of the air supply line 130, the gas supply line 140, i.e., inside the housing 110.

The igniter 152 is actuated by the control unit 154 that senses the opening of the air supply valve 132 and the gas supply valve 142 to ignite the ignition fluid introduced into the housing 110 to thereby supply the immersion nozzle 25- 1).

The pressure applied to the air supply valve 132 and the gas supply valve 142 is lost and as a result the air supply valve 132 and the gas The supply valve 142 is closed.

Therefore, the ignition means 150 may combust the air supplied from the air supply line 130 and the gas supply line 140 and the fuel gas (such as liquefied natural gas and liquefied propane gas) to inject the upper portion of the housing 110 Preheating is performed on the immersion nozzle 25-1 inserted from the hole 114. [ In this case, the preheating temperature is preferably preheated to about 1300 degrees to about 1100 degrees in consideration of the temperature of the molten steel (M).

The immersion nozzle preheating apparatus 100 according to the present invention formed as described above is disposed in the housing 110 and the upper portion of the housing 110 to define a lower portion of the preheated immersion nozzle 25-1 therein. The upper part of the immersion nozzle 25-1 to be preheated is opened by the pressure of the immersion nozzle 25-1 mounted on the holder 120, and air and fuel gas are introduced into the housing 110. By immersing the air and gas supply line (130,140) to supply and the ignition means 150 for operating the igniter 140 disposed inside the housing 110 by detecting the open state of the air and gas supply line (130,140), Not only can the nozzle 25-1 be preheated easily, but the trouble of preheating of the immersion nozzle 25-1 can be solved.

The plurality of immersion nozzle preheating apparatuses 100 according to the present invention can preheat a plurality of immersion nozzles 25-1 and can prevent the immersion nozzle 25-1 from being heated The accident can be prevented in advance.

The immersion nozzle preheating apparatus 100 as described above is not limited to the construction and operation of the embodiments described above. The above embodiments may be configured so that all or some of the embodiments may be selectively combined into various modifications.

100: immersion nozzle preheating device 110: housing
112: exhaust port 114: insertion hole
120: cradle 122: mounting ring
124: cylinder 126: rod
128: opening and closing flow path 130: air supply line
132: air supply valve 140: gas supply line
142: gas supply valve 150: ignition means
52: igniter 154: control unit

Claims (5)

A housing having a lower portion of the immersion nozzle preheated through the insertion hole of the upper surface thereof;
A cradle on which an upper portion of the immersion nozzle to be preheated is mounted;
An air supply line and a gas supply line extending into the housing with an air supply valve and a gas supply valve opened by the pressure of the immersion nozzle placed on the mount stand; And
And ignition means for igniting an ignition fluid supplied into the housing by sensing the open state of the air supply valve and the gas supply valve.
The method according to claim 1,
The cradle,
A cylinder disposed perpendicularly to an upper surface of the housing so as not to interfere with the insertion hole;
A rod that ascends and descends along the inside of the cylinder; And
And a mounting ring disposed on the rod and mounted on an upper portion of the immersion nozzle inserted into the insertion hole of the housing.
The method according to claim 2,
Wherein the cylinder, the air supply valve, and the gas supply valve are connected by an open / close flow path,
Wherein the air supply valve and the gas supply valve are operated to open and close by the opening and closing flow path whose pressure is raised and lowered by the immersion nozzle held in the stationary ring and the working fluid in the cylinder.
The method according to claim 1,
Wherein the ignition means comprises:
An igniter disposed within the housing adjacent to the proximal end of the air supply line and the gas supply line; And
And a controller for sensing the open state of the air supply valve and the gas supply valve to operate the igniter.
The method according to claim 1,
And an exhaust port disposed on the upper surface of the housing so as not to interfere with the insertion hole and the mount stand.

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